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Creating a cluster with multi-architecture compute machines on Azure - Configuring multi-architecture compute machines on an OpenShift cluster | Postinstallation configuration | OpenShift Container Platform 4.16
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To deploy an Azure cluster with multi-architecture compute machines, you must first create a single-architecture Azure installer-provisioned cluster that uses the multi-architecture installer binary. For more information on Azure installations, see Installing a cluster on Azure with customizations.

You can also migrate your current cluster with single-architecture compute machines to a cluster with multi-architecture compute machines. For more information, see Migrating to a cluster with multi-architecture compute machines.

After creating a multi-architecture cluster, you can add nodes with different architectures to the cluster.

Verifying cluster compatibility

Before you can start adding compute nodes of different architectures to your cluster, you must verify that your cluster is multi-architecture compatible.

Prerequisites
  • You installed the OpenShift CLI (oc).

Procedure
  1. Log in to the OpenShift CLI (oc).

  2. You can check that your cluster uses the architecture payload by running the following command:

    $ oc adm release info -o jsonpath="{ .metadata.metadata}"
Verification
  • If you see the following output, your cluster is using the multi-architecture payload:

    {
     "release.openshift.io/architecture": "multi",
     "url": "https://access.redhat.com/errata/<errata_version>"
    }

    You can then begin adding multi-arch compute nodes to your cluster.

  • If you see the following output, your cluster is not using the multi-architecture payload:

    {
     "url": "https://access.redhat.com/errata/<errata_version>"
    }

    To migrate your cluster so the cluster supports multi-architecture compute machines, follow the procedure in Migrating to a cluster with multi-architecture compute machines.

Creating a 64-bit ARM boot image using the Azure image gallery

The following procedure describes how to manually generate a 64-bit ARM boot image.

Prerequisites
  • You installed the Azure CLI (az).

  • You created a single-architecture Azure installer-provisioned cluster with the multi-architecture installer binary.

Procedure
  1. Log in to your Azure account:

    $ az login
  2. Create a storage account and upload the aarch64 virtual hard disk (VHD) to your storage account. The OpenShift Container Platform installation program creates a resource group, however, the boot image can also be uploaded to a custom named resource group:

    $ az storage account create -n ${STORAGE_ACCOUNT_NAME} -g ${RESOURCE_GROUP} -l westus --sku Standard_LRS (1)
    1 The westus object is an example region.
  3. Create a storage container using the storage account you generated:

    $ az storage container create -n ${CONTAINER_NAME} --account-name ${STORAGE_ACCOUNT_NAME}
  4. You must use the OpenShift Container Platform installation program JSON file to extract the URL and aarch64 VHD name:

    1. Extract the URL field and set it to RHCOS_VHD_ORIGIN_URL as the file name by running the following command:

      $ RHCOS_VHD_ORIGIN_URL=$(oc -n openshift-machine-config-operator get configmap/coreos-bootimages -o jsonpath='{.data.stream}' | jq -r '.architectures.aarch64."rhel-coreos-extensions"."azure-disk".url')
    2. Extract the aarch64 VHD name and set it to BLOB_NAME as the file name by running the following command:

      $ BLOB_NAME=rhcos-$(oc -n openshift-machine-config-operator get configmap/coreos-bootimages -o jsonpath='{.data.stream}' | jq -r '.architectures.aarch64."rhel-coreos-extensions"."azure-disk".release')-azure.aarch64.vhd
  5. Generate a shared access signature (SAS) token. Use this token to upload the RHCOS VHD to your storage container with the following commands:

    $ end=`date -u -d "30 minutes" '+%Y-%m-%dT%H:%MZ'`
    $ sas=`az storage container generate-sas -n ${CONTAINER_NAME} --account-name ${STORAGE_ACCOUNT_NAME} --https-only --permissions dlrw --expiry $end -o tsv`
  6. Copy the RHCOS VHD into the storage container:

    $ az storage blob copy start --account-name ${STORAGE_ACCOUNT_NAME} --sas-token "$sas" \
     --source-uri "${RHCOS_VHD_ORIGIN_URL}" \
     --destination-blob "${BLOB_NAME}" --destination-container ${CONTAINER_NAME}

    You can check the status of the copying process with the following command:

    $ az storage blob show -c ${CONTAINER_NAME} -n ${BLOB_NAME} --account-name ${STORAGE_ACCOUNT_NAME} | jq .properties.copy
    Example output
    {
     "completionTime": null,
     "destinationSnapshot": null,
     "id": "1fd97630-03ca-489a-8c4e-cfe839c9627d",
     "incrementalCopy": null,
     "progress": "17179869696/17179869696",
     "source": "https://rhcos.blob.core.windows.net/imagebucket/rhcos-411.86.202207130959-0-azure.aarch64.vhd",
     "status": "success", (1)
     "statusDescription": null
    }
    1 If the status parameter displays the success object, the copying process is complete.
  7. Create an image gallery using the following command:

    $ az sig create --resource-group ${RESOURCE_GROUP} --gallery-name ${GALLERY_NAME}

    Use the image gallery to create an image definition. In the following example command, rhcos-arm64 is the name of the image definition.

    $ az sig image-definition create --resource-group ${RESOURCE_GROUP} --gallery-name ${GALLERY_NAME} --gallery-image-definition rhcos-arm64 --publisher RedHat --offer arm --sku arm64 --os-type linux --architecture Arm64 --hyper-v-generation V2
  8. To get the URL of the VHD and set it to RHCOS_VHD_URL as the file name, run the following command:

    $ RHCOS_VHD_URL=$(az storage blob url --account-name ${STORAGE_ACCOUNT_NAME} -c ${CONTAINER_NAME} -n "${BLOB_NAME}" -o tsv)
  9. Use the RHCOS_VHD_URL file, your storage account, resource group, and image gallery to create an image version. In the following example, 1.0.0 is the image version.

    $ az sig image-version create --resource-group ${RESOURCE_GROUP} --gallery-name ${GALLERY_NAME} --gallery-image-definition rhcos-arm64 --gallery-image-version 1.0.0 --os-vhd-storage-account ${STORAGE_ACCOUNT_NAME} --os-vhd-uri ${RHCOS_VHD_URL}
  10. Your arm64 boot image is now generated. You can access the ID of your image with the following command:

    $ az sig image-version show -r $GALLERY_NAME -g $RESOURCE_GROUP -i rhcos-arm64 -e 1.0.0

    The following example image ID is used in the recourseID parameter of the compute machine set:

    Example resourceID
    /resourceGroups/${RESOURCE_GROUP}/providers/Microsoft.Compute/galleries/${GALLERY_NAME}/images/rhcos-arm64/versions/1.0.0

Creating a 64-bit x86 boot image using the Azure image gallery

The following procedure describes how to manually generate a 64-bit x86 boot image.

Prerequisites
  • You installed the Azure CLI (az).

  • You created a single-architecture Azure installer-provisioned cluster with the multi-architecture installer binary.

Procedure
  1. Log in to your Azure account by running the following command:

    $ az login
  2. Create a storage account and upload the x86_64 virtual hard disk (VHD) to your storage account by running the following command. The OpenShift Container Platform installation program creates a resource group. However, the boot image can also be uploaded to a custom named resource group:

    $ az storage account create -n ${STORAGE_ACCOUNT_NAME} -g ${RESOURCE_GROUP} -l westus --sku Standard_LRS (1)
    1 The westus object is an example region.
  3. Create a storage container using the storage account you generated by running the following command:

    $ az storage container create -n ${CONTAINER_NAME} --account-name ${STORAGE_ACCOUNT_NAME}
  4. Use the OpenShift Container Platform installation program JSON file to extract the URL and x86_64 VHD name:

    1. Extract the URL field and set it to RHCOS_VHD_ORIGIN_URL as the file name by running the following command:

      $ RHCOS_VHD_ORIGIN_URL=$(oc -n openshift-machine-config-operator get configmap/coreos-bootimages -o jsonpath='{.data.stream}' | jq -r '.architectures.x86_64."rhel-coreos-extensions"."azure-disk".url')
    2. Extract the x86_64 VHD name and set it to BLOB_NAME as the file name by running the following command:

      $ BLOB_NAME=rhcos-$(oc -n openshift-machine-config-operator get configmap/coreos-bootimages -o jsonpath='{.data.stream}' | jq -r '.architectures.x86_64."rhel-coreos-extensions"."azure-disk".release')-azure.x86_64.vhd
  5. Generate a shared access signature (SAS) token. Use this token to upload the RHCOS VHD to your storage container by running the following commands:

    $ end=`date -u -d "30 minutes" '+%Y-%m-%dT%H:%MZ'`
    $ sas=`az storage container generate-sas -n ${CONTAINER_NAME} --account-name ${STORAGE_ACCOUNT_NAME} --https-only --permissions dlrw --expiry $end -o tsv`
  6. Copy the RHCOS VHD into the storage container by running the following command:

    $ az storage blob copy start --account-name ${STORAGE_ACCOUNT_NAME} --sas-token "$sas" \
     --source-uri "${RHCOS_VHD_ORIGIN_URL}" \
     --destination-blob "${BLOB_NAME}" --destination-container ${CONTAINER_NAME}

    You can check the status of the copying process by running the following command:

    $ az storage blob show -c ${CONTAINER_NAME} -n ${BLOB_NAME} --account-name ${STORAGE_ACCOUNT_NAME} | jq .properties.copy
    Example output
    {
     "completionTime": null,
     "destinationSnapshot": null,
     "id": "1fd97630-03ca-489a-8c4e-cfe839c9627d",
     "incrementalCopy": null,
     "progress": "17179869696/17179869696",
     "source": "https://rhcos.blob.core.windows.net/imagebucket/rhcos-411.86.202207130959-0-azure.aarch64.vhd",
     "status": "success", (1)
     "statusDescription": null
    }
    1 If the status parameter displays the success object, the copying process is complete.
  7. Create an image gallery by running the following command:

    $ az sig create --resource-group ${RESOURCE_GROUP} --gallery-name ${GALLERY_NAME}
  8. Use the image gallery to create an image definition by running the following command:

    $ az sig image-definition create --resource-group ${RESOURCE_GROUP} --gallery-name ${GALLERY_NAME} --gallery-image-definition rhcos-x86_64 --publisher RedHat --offer x86_64 --sku x86_64 --os-type linux --architecture x64 --hyper-v-generation V2

    In this example command, rhcos-x86_64 is the name of the image definition.

  9. To get the URL of the VHD and set it to RHCOS_VHD_URL as the file name, run the following command:

    $ RHCOS_VHD_URL=$(az storage blob url --account-name ${STORAGE_ACCOUNT_NAME} -c ${CONTAINER_NAME} -n "${BLOB_NAME}" -o tsv)
  10. Use the RHCOS_VHD_URL file, your storage account, resource group, and image gallery to create an image version by running the following command:

    $ az sig image-version create --resource-group ${RESOURCE_GROUP} --gallery-name ${GALLERY_NAME} --gallery-image-definition rhcos-arm64 --gallery-image-version 1.0.0 --os-vhd-storage-account ${STORAGE_ACCOUNT_NAME} --os-vhd-uri ${RHCOS_VHD_URL}

    In this example, 1.0.0 is the image version.

  11. Optional: Access the ID of the generated x86_64 boot image by running the following command:

    $ az sig image-version show -r $GALLERY_NAME -g $RESOURCE_GROUP -i rhcos-x86_64 -e 1.0.0

    The following example image ID is used in the recourseID parameter of the compute machine set:

    Example resourceID
    /resourceGroups/${RESOURCE_GROUP}/providers/Microsoft.Compute/galleries/${GALLERY_NAME}/images/rhcos-x86_64/versions/1.0.0

Adding a multi-architecture compute machine set to your Azure cluster

After creating a multi-architecture cluster, you can add nodes with different architectures.

You can add multi-architecture compute machines to a multi-architecture cluster in the following ways:

  • Adding 64-bit x86 compute machines to a cluster that uses 64-bit ARM control plane machines and already includes 64-bit ARM compute machines. In this case, 64-bit x86 is considered the secondary architecture.

  • Adding 64-bit ARM compute machines to a cluster that uses 64-bit x86 control plane machines and already includes 64-bit x86 compute machines. In this case, 64-bit ARM is considered the secondary architecture.

To create a custom compute machine set on Azure, see "Creating a compute machine set on Azure".

Before adding a secondary architecture node to your cluster, it is recommended to install the Multiarch Tuning Operator, and deploy a ClusterPodPlacementConfig custom resource. For more information, see "Managing workloads on multi-architecture clusters by using the Multiarch Tuning Operator".

Prerequisites
  • You installed the OpenShift CLI (oc).

  • You created a 64-bit ARM or 64-bit x86 boot image.

  • You used the installation program to create a 64-bit ARM or 64-bit x86 single-architecture Azure cluster with the multi-architecture installer binary.

Procedure
  1. Log in to the OpenShift CLI (oc).

  2. Create a YAML file, and add the configuration to create a compute machine set to control the 64-bit ARM or 64-bit x86 compute nodes in your cluster.

    Example MachineSet object for an Azure 64-bit ARM or 64-bit x86 compute node
    apiVersion: machine.openshift.io/v1beta1
    kind: MachineSet
    metadata:
      labels:
        machine.openshift.io/cluster-api-cluster: <infrastructure_id>
        machine.openshift.io/cluster-api-machine-role: worker
        machine.openshift.io/cluster-api-machine-type: worker
      name: <infrastructure_id>-machine-set-0
      namespace: openshift-machine-api
    spec:
      replicas: 2
      selector:
        matchLabels:
          machine.openshift.io/cluster-api-cluster: <infrastructure_id>
          machine.openshift.io/cluster-api-machineset: <infrastructure_id>-machine-set-0
      template:
        metadata:
          labels:
            machine.openshift.io/cluster-api-cluster: <infrastructure_id>
            machine.openshift.io/cluster-api-machine-role: worker
            machine.openshift.io/cluster-api-machine-type: worker
            machine.openshift.io/cluster-api-machineset: <infrastructure_id>-machine-set-0
        spec:
          lifecycleHooks: {}
          metadata: {}
          providerSpec:
            value:
              acceleratedNetworking: true
              apiVersion: machine.openshift.io/v1beta1
              credentialsSecret:
                name: azure-cloud-credentials
                namespace: openshift-machine-api
              image:
                offer: ""
                publisher: ""
                resourceID: /resourceGroups/${RESOURCE_GROUP}/providers/Microsoft.Compute/galleries/${GALLERY_NAME}/images/rhcos-arm64/versions/1.0.0 (1)
                sku: ""
                version: ""
              kind: AzureMachineProviderSpec
              location: <region>
              managedIdentity: <infrastructure_id>-identity
              networkResourceGroup: <infrastructure_id>-rg
              osDisk:
                diskSettings: {}
                diskSizeGB: 128
                managedDisk:
                  storageAccountType: Premium_LRS
                osType: Linux
              publicIP: false
              publicLoadBalancer: <infrastructure_id>
              resourceGroup: <infrastructure_id>-rg
              subnet: <infrastructure_id>-worker-subnet
              userDataSecret:
                name: worker-user-data
              vmSize: Standard_D4ps_v5 (2)
              vnet: <infrastructure_id>-vnet
              zone: "<zone>"
    1 Set the resourceID parameter to either arm64 or amd64 boot image.
    2 Set the vmSize parameter to the instance type used in your installation. Some example instance types are Standard_D4ps_v5 or D8ps.
  3. Create the compute machine set by running the following command:

    $ oc create -f <file_name> (1)
    1 Replace <file_name> with the name of the YAML file with compute machine set configuration. For example: arm64-machine-set-0.yaml, or amd64-machine-set-0.yaml.
Verification
  1. Verify that the new machines are running by running the following command:

    $ oc get machineset -n openshift-machine-api

    The output must include the machine set that you created.

    Example output
    NAME                                                DESIRED  CURRENT  READY  AVAILABLE  AGE
    <infrastructure_id>-machine-set-0                   2        2      2          2  10m
  2. You can check if the nodes are ready and schedulable by running the following command:

    $ oc get nodes